鄂西渝东下古生界海相页岩饱和烃组成特征及其指示意义

doi:10.11743/ogg20180202

Abstract

Abstract:

Organic-rich marine shales in the Lower Cambrian Shuijingtuo (Niutitang) Formation,the Upper Ordovician Wufeng Formation and the Lower Silurian Longmaxi Formation of western Hubei-eastern Chongqing area are very attractive targets for shale gas exploration in southern China.This research shows that the maximum paleogeotemperature experienced by the Shuijingtuo Formation ranges from 280℃ to 300℃,while the maximum paleogeotemperature of the Wufeng Formation and the Longmaxi Formation ranges from 200℃ to 220℃.The organic matter of the three formations is over-mature,with the vitrinite reflectance (R_o) for the Shuijingtuo Formation varying from 3.90% to 4.50%,while that for the Wufeng Formation and the Longmaxi Formation from 2.45% to 3.00%.However,nearly a complete series of n-alkanes mostly with bimodal distributions,isoprenoid alkenes,steranes,and terpanes have been observed in saturated hydrocarbons from the sampled shales' chloroform extract.This demonstrates that the conversion from liquid hydrocarbons to gaseous hydrocarbons (i.e. cyclo-polycondensation and hydrocracking) has been restricted within the shale strata,and thus the carbon skeleton of typical saturated hydrocarbon biomarkers could preserve at 200℃ to 300℃ for 50 to 180 Ma.What is also shown by the research is that some saturated hydrocarbon biomarkers in over-mature shales have not lost their ability to indicate maturity and biogenesis completely.Judging from the carbon number range and bimodal distributions of n-alkanes,and C₂₃ tricyclic terpane/C₃₀ hopance ratios in the sampled shales,the shales in the Shuijingtuo Formation have a higher level of organic maturity and the prokaryote is a major source of their organic matter,while the organic parent substance for Wufeng shales and Longmaxi shales are mainly derived from bacteria and alga.

Key words: organic matter, over-maturity, saturated hydrocarbon, shale, Lower Paleozoic, western Hubei-eastern Chongqing area

CLC Number:

TE122.1

Xu Shuhui, He Sheng, Zhu Gangtian, Liu Ruobing, Lu Yaqiu, Wei Sile. Characteristics of saturated hydrocarbons from Lower Paleozoic marine shales in western Hubei-eastern Chongqing area and their indications[J]. Oil & Gas Geology, 2018, 39(2): 217-228.

References

[1] 张金川,徐波,聂海宽,等.中国页岩气资源勘探潜力[J].天然气工业,2008,28(6):136-140,159-160. Zhang Jinchuan,Xu Bo,Nie Haikuan,et al.Exploration potential of shale gas resources in China[J].Natural Gas Industry,2008,28(6):136-140,159-160.
[2] 邹才能,董大忠,杨桦,等.中国页岩气形成条件及勘探实践[J].天然气工业,2011,31(12):26-39,125. Zou Caineng,Dong Dazhong,Yang Hua,et al.Conditions of shale gas accumulation and exploration practices in China[J].Natural Gas Industry,2011,31(12):26-39,125.
[3] 郭旭升,郭彤楼,魏志红,等.中国南方页岩气勘探评价的几点思考[J].中国工程科学,2012,14(6):101-105,112. Guo Xusheng,Guo Tonglou,Wei Zhihong,et al.Thoughts on shale gas exploration in southern China[J].Engineering Sciences,2012,14(6):101-105,112.
[4] 王志刚.涪陵焦石坝地区页岩气水平井压裂改造实践与认识[J].石油与天然气地质,2014,35(3):425-430. Wang Zhigang.Practice and cognition of shale gas horizontal well fracturing stimulation in Jiaoshiba of Fuling area[J].Oil & Gas Geology,2014,35(3):425-430.
[5] 何治亮,聂海宽,张钰莹.四川盆地及其周缘奥陶系五峰组-志留系龙马溪组页岩气富集主控因素分析[J].地学前缘,2016,23(2):8-17. He Zhiliang,Nie Haikuan,Zhang Yuying.The main factors of shale gas enrichment of Ordovician Wufeng Formation-Silurian Longmaxi Formation in the Sichuan Basin and its adjacent areas[J].Earth Science Frontiers,2016,23(2):8-17.
[6] 翟刚毅,包书景,庞飞,等.武陵山复杂构造区古生界海相油气实现重大突破[J].地球学报,2016,37(6):657-662. Zhai Gangyi,Bao Shujing,Pang Fei,et al.Breakthrough of the natural gas of Paleozoic marine strata in Wuling mountain complex tectonic zone[J].Acta Geoscientica Sinica,2016,37(6):657-662.
[7] 梁狄刚,郭彤楼,陈建平,等.中国南方海相生烃成藏研究的若干新进展(二)南方四套区域性海相烃源岩的地球化学特征[J].海相油气地质,2009,14(1):1-15. Liang Digang,Guo Tonglou,Chen Jianping,et al.Some progresses on studies of hydrocarbon generation and accumulation in marine sedimentary regions,southern China (Part 2):Geochemical characteristics of four suits of regional marine source rocks,South China[J].Marine Origin Petroleum Geology,2009,14(1):1-15.
[8] 王琛,林丽,李德亮,等.黔西纳雍地区下寒武统牛蹄塘组黑色岩系生物标志物的特征[J].地质通报,2011,30(1):106-111. Wang Chen,Lin Li,Li Deliang,et al.Characteristics of biomarkers of the black rock series of Lower Cambrian Niutitang Formation in the Nayong area,western Guizhou[J],China.Geological Bulletin of China,2011,30(1):106-111.
[9] 杨平,汪正江,谢渊,等.黔北下寒武统牛蹄塘组烃源岩的生物标志物特征和沉积环境[J].地质通报,2012,31(11):1910-1921. Yang Ping,Wang Zhengjiang,Xie Yuan,et al.The biomarker characteristics and sedimentary environment of Lower Cambrian Niutitang Formation source rock in northern Guizhou[J].Geological Bulletin of China,2012,31(11):1910-1921.
[10] 包建平,斯春松,蒋兴超,等.黔北坳陷过成熟烃源岩和固体沥青中正构烷烃系列的双峰态分布[J].沉积学报,2016,34(1):181-190. Bao Jianping,Si Chunsong,Jiang Xingchao,et al.The bimodal distributions of n-alkanes in the post-mature marine source rocks and solid bitumenfrom the northern Guizhou depression[J].Acta Sedimentologica Sinica,2016,34(1):181-190.
[11] Jin X,Pan C,Yu S,et al.Organic geochemistry of marine source rocks and pyrobitumen-containing reservoir rocks of the Sichuan Basin and neighbouring areas,SW China[J].Marine and Petroleum Geology,2014,56(3):147-165.
[12] Tuo J,Wu C,Zhang M.Organic matter properties and shale gas potential of Paleozoic shales in Sichuan Basin,China[J].Journal of Natural Gas Science and Engineering,2016,28(57):434-446.
[13] 梅廉夫,刘昭茜,汤济广,等.南方多旋回构造作用制约下的中、古生界海相油气构造-成藏旋回[J].石油与天然气地质,2009,30(5):589-597,607. Mei Lianfu,Liu Zhaoqian,Tang Jiguang,et al.Tectonic-pooling cycles controlled by polycyclic tectonism in the Mesozoic-Palaeozoic marine strata of South China[J].Oil & Gas Geology,2009,30(5):589-597,607.
[14] 王清晨,林伟.中国南方古生界海相烃源岩的主变形期[J].石油与天然气地质,2008,29(5):582-588,622. Wang Qingchen,Lin Wei.Main deformation phases of the Paleozoic marine hydrocarbon source rocks in South China[J].Oil & Gas Geology,2008,29(5):582-588,622.
[15] 刘德汉,肖贤明,田辉,等.固体有机质拉曼光谱参数计算样品热演化程度的方法与地质应用[J].科学通报,2013,58(13):1228-1241. Liu Dehan,Xiao Xianming,Tian Hui,et al.Sample maturation calculated using Raman spectroscopic parameters for solid organics:Methodology and geological applications[J].Chinese Science Bulletin,2013,58(13):1228-1241.
[16] 卢庆治,马永生,郭彤楼,等.鄂西-渝东地区热史恢复及烃源岩成烃史[J].地质科学,2007,42(1):189-198. Lu Qingzhi,Ma Yongsheng,Guo Tonglou,et al.Thermal history and hydrocarbon generation history in westernHubei-eastern Chongqing area[J].Chinese Journal of Geology,2007,42(1):189-198.
[17] 梅廉夫,刘昭茜,汤济广,等.湘鄂西-川东中生代陆内递进扩展变形:来自裂变径迹和平衡剖面的证据[J].地球科学(中国地质大学学报),2010,35(2):161-174. Mei Lianfu,Liu Zhaoqian,Yang Jiguang,et al.Mesozoic intra-continental progressive deformation in western Hunan-Hubei-eastern Sichuan provinces of China:Evidence from apatite fission track and balanced cross-section[J].Earth Science(Journal of China University of Geosciences),2010,35(2):161-174.
[18] 王洪江,刘光祥.中上扬子区热场分布与演化[J].石油实验地质,2011,33(2):160-164. Wang Hongjiang,Liu Guangxiang.Distribution and evolution of thermal field inMiddle and Upper Yangtze region[J].Petroleum Geology and Experiment,2011,33(2):160-164.
[19] 石红才,施小斌,杨小秋,等.鄂西渝东方斗山-石柱褶皱带中新生代隆升剥蚀过程及构造意义[J].地球物理学进展,2011,26(6):1993-2002. Shi Hongcai,Shi Xiaobin,Yang Xiaoqiu,et al.Exhumation process of the Fangdoushan-Shizhu fold belt in Meso-Neozoic and its tectonic significance in western Hubei-eastern Chongqing[J].Progress in Geophysics,2011,26(6):1993-2002.
[20] 张建坤,何生,易积正,等.岩石热声发射和盆模技术研究中扬子区西部下古生界海相页岩最高古地温和热成熟史[J].石油学报,2014,35(1):58-67. Zhang Jiankun,He Sheng,Yi Jizheng,et al.Rock thermo-acoustic emission and basin modeling technologies applied to the study of maximum paleotemperatures and thermal maturity histories of Lower Paleozoic marine shales in the western Middle Yangtze area[J].Acta Petrolei Sinica,2014,35(1):58-67.
[21] Sweeney J,Burnham A.Evaluation of a simple model of vitrinite reflectance based on chemical kinetics[J].AAPG Bulletin,1990,74(10):1559-1570.
[22] 张琴,王红岩,拜文华,等.南方海相志留系页岩有机质类型恢复研究[J].断块油气田,2013,20(2):154-156. Zhang Qin,Wang Hongyan,Bai Wenhua,et al.Restoration of organic matter type in Silurian marine shale,South China[J].Fault-Block Oil and Gas Field,2013,20(2):154-156.
[23] 腾格尔,高长林,胡凯,等.上扬子北缘下组合优质烃源岩分布及生烃潜力评价[J].天然气地球科学,2007,18(2):254-259. Teng Ge'er,Gao Changlin,Hu Kai,et al.High quality source rocks of lower combination in the northernUpper-Yangtze area and their hydrocarbon potential[J].Natural Gas Geoscience,2007,18(2):254-259.
[24] 孟凡巍,周传明,燕夔,等.通过C₂₇/C₂₉甾烷和有机碳同位素来判断早古生代和前寒武纪的烃源岩的生物来源[J].微体古生物学报,2006,23(1):51-56. Meng Fanwei,Zhou Chuanming,Yan Kui,et al.Biological origin of early Paleozoic and Precambrian hydrocarbon source rocks based on C₂₇/C₂₉ sterane ratio and organic carbon isotope[J].Acta Micropalaeontologica Sinica,2006,23(1):51-56.
[25] Tissot B,Welte D.Petroleum formation and occurrence:A new approach to oil and gas exploration[M].Berlin,DEU:Springer-Verlag.1978:148-184.
[26] Price L.Thermal stability of hydrocarbons in nature:Limits,evidence,characteristics,and possible controls[J].Geochim Cosmochim Acta,1993,57(20):3261-3280.
[27] 邱军利,夏燕青,雷天柱.两种热模拟体系下热解产物的相关性研究[J].天然气地球科学,2011,22(1):144-148. Qiu Junli,Xia Yanqing,Lei Tianzhu.Correlation study of pyrolysis product between two different thermal simulation systems[J].Natural Gas Geoscience,2011,22(1):144-148.
[28] 彭平安,秦艳,张辉,等.封闭体系有机质与有机碳氢氮恢复动力学研究[J].海相油气地质,2008,13(2):27-36. Peng Ping'an,Qin Yan,Zhang Hui,et al.Kinetics of kerogen transformation by heating in closed system[J].Marine Origin Petroleum Geology,2008,13(2):27-36.
[29] Theng B.Formation and properties of clay-polymer complexes[M].Amsterdam:Elsevies,1979:1-154.
[30] Keil R,Hedges J.Sorption of organic matter to mineral surfaces and the preservation of organic matter in coastal marine sediments[J].Chemical Geology,1993,107(3-4):385-388.
[31] Mayer L.Surface area control of organic carbon accumulation in continental shelf sediments[J].Geochimica et Cosmochimica Acta,1994,58(4):1271-1284.
[32] Bergamaschi B,Tsamakis E,Keil R,et al.The effect of grain size and surface area on organic matter,lignin and carbohydrate concentration,and molecular compositions in Peru Margin sediments[J].Geochimica et Cosmochimica Acta,1997,61(6):1247-1260.
[33] Chenu C,Plante A.Clay-sized organo-mineral complexes in a cultivation chronosequence:Revisting the concept of the ‘primary organo-mineral complex’[J].European Journal of Soil Science,2006,57(4):596-607.
[34] 叶文青,蔡进功,樊馥,等.泥质烃源岩密度分级分离与有机碳分配[J].高校地质学报,2009,15(4):547-556. Ye Wenqing,Cai Jingong,Fan Fu,et al.Argillaceous hydrocarbon source sock density separation and distribution of organic carbon[J].Geological Journal of China Universities,2009,15(4):547-556.
[35] 蔡进功,卢龙飞,丁飞,等.烃源岩中黏土与可溶有机质相互作用研究展望[J].同济大学学报(自然科学版),2009,37(12):1679-1684. Cai Jingong,Lu Longfei,Ding Fei,et al.Significance of interaction between soluble organic matterand clay minerals in muddy source rocks[J].Journal of Tongji University(Natural Science),2009,37(12):1679-1684.
[36] Yang R,He S,Hu Q,et al.Geochemical characteristics and origin of natural gas from Wufeng-Longmaxi shales of the Fuling gas field,Sichuan Basin (China)[J].International Journal of Coal Geology,2017,171:1-11.
[37] Ourisson G,Albrecht P,Rohmer M.Predictive microbial biochemistry-from molecular fossils to procaryotic membranes[J].Trends in Biochemical Sciences,1982,7(7):236-239.
[38] Volkman J,Banks M,Denwer K,et al.Biomarker composition and depositional setting of Tasmanite oil shale from northern Tasmania,Australia[C]//14th International Meeting on Organic Geochemistry,Paris.1989:18-22.
[39] Azevedo D,Neto F,Simoneit B,et al.Novel series of tricyclic aromatic terpanes characterized in Tasmanian tasmanite[J].Organic Geochemistry,1992,18(1):9-16.
[40] Peters K,Walters C,Moldowan J.The biomarker guide:Biomarkers and isotopes in petroleum exploration and earth history[M].Cambridge,UK:Cambridge University Press.2005:76-83.
[41] 李景贵.高过成熟海相碳酸盐岩抽提物不寻常的正构烷烃分布及其成因[J].石油勘探与开发,2002,29(4):8-11. Li Jinggui.Unusual distribution and its origin of n-alkanes in extracts of marine carbonate rocks with high maturity and over maturity[J].Petroleum Exploration and Development,2002,29(4):8-11.
[42] 刘宝泉,方杰.冀北宽城地区中上元古界、寒武系有机质热演化特征及油源探讨[J].石油实验地质,1989,11(1):16-32. Liu Baoquan,Fangjie.Research on petroleum source and maturation characteristics of the organic matter of Cambrian and Middle-Upper Proterozoic in Kuancheng region of northern Hubei province[J].Petroleum Geology and Experiment,1989,11(1):16-32.
[43] 刘宝泉,贾蓉芬.中上元古界生油岩中正、异构烷烃热演化的特征及热模拟实验[J].地球化学,1990,(3):242-248. Liu Baoquan,Jia Rongfen.Thermal evolutionfeatures of nor-and iso-alkanes in the Middle-Upper Proterozoic source rocks-A thermal simulating experiment[J].Geochimica,1990,(3):242-248.
[44] 王屿涛.平地泉组泥岩热模拟实验中的生物标志化合物[J].新疆石油地质,1992,13(3):240-250. Wang Yutao.Biomarkers from Pindiquan(P2) shaleby thermal modelling experiments[J].Xinjiang Petroleum Geology,1992,13(3):240-250.
[45] 方杰,刘宝泉,郭树之,等.张家口下花园青白口系下马岭组灰质页岩热模拟实验[J].高校地质学报,2002,8(3):345-355. Fang Jie,Liu Baoquan,Guo Shuzhi,et al.Thermal experiments on lime-shale from theUpper Proterozoic Xiamaling Formation at Xiahuayuan,Zhangjiakou[J].Geological Journal of China Universities,2002,8(3):345-355.
[46] George S.Effect of igneous intrusion on the organic geochemistry of a siltstone and an oil shale horizon in the Midland Valley of Scotland[J].Organic Geochemistry,1992,18(5):705-723.
[47] 段毅,周世新.塔里木盆地石炭系烃源岩热模拟实验研究-Ⅱ.生物标志化合物的组成和演化[J].石油与天然气地质,2001,22(1):13-16. Duan Yi,Zhou Shixin.Study on thermal simulation of carboniferous source rocks in Tarim Basin:Ⅱ Composition and evolution of biomarkers[J].Oil & Gas Geology,2001,22(1):13-16.

Characteristics of saturated hydrocarbons from Lower Paleozoic marine shales in western Hubei-eastern Chongqing area and their indications

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

[1]	Huimin LIU, Youshu BAO, Maowen LI, Zheng LI, Lianbo WU, Rifang ZHU, Dayang WANG, Xin WANG. Geochemical parameters for evaluating shale oil enrichment and mobility： A case study of shales in the Bakken Formation， Williston Basin and the Shahejie Formation， Jiyang Depression [J]. Oil & Gas Geology, 2024, 45(3): 622-636.
[2]	Xiugang PU, Jiangchang DONG, Gongquan CHAI, Shunyao SONG, Zhannan SHI, Wenzhong HAN, Wei ZHANG, Delu XIE. Enrichment model of high-abundance organic matter in shales in the 2^nd member of the Paleogene Kongdian Formation， Cangdong Sag， Bohai Bay Basin [J]. Oil & Gas Geology, 2024, 45(3): 696-709.
[3]	Rui FANG, Yuqiang JIANG, Changcheng YANG, Haibo DENG, Chan JIANG, Haitao HONG, Song TANG, Yifan GU, Xun ZHU, Shasha SUN, Guangyin CAI. Occurrence states and mobility of shale oil in different lithologic assemblages in the Jurassic Lianggaoshan Formation， Sichuan Basin [J]. Oil & Gas Geology, 2024, 45(3): 752-769.
[4]	Jun LI, Youlong ZOU, Jing LU. Well-log-based assessment of movable oil content in lacustrine shale oil reservoirs： A case study of the 2^nd member of the Paleogene Funing Formation， Subei Basin [J]. Oil & Gas Geology, 2024, 45(3): 816-826.
[5]	Xiaoyu DU, Zhijun JIN, Lianbo ZENG, Guoping LIU, Sen YANG, Xinping LIANG, Guoqing LU. Evaluation of natural fracture effectiveness in deep lacustrine shale oil reservoirs based on formation microresistivity imaging logs [J]. Oil & Gas Geology, 2024, 45(3): 852-865.
[6]	Caineng ZOU, Dazhong DONG, Wei XIONG, Guoyou FU, Qun ZHAO, Wen LIU, Weiliang KONG, Qin ZHANG, Guangyin CAI, Yuman WANG, Feng LIANG, Hanlin LIU, Zhen QIU. Advances， challenges， and countermeasures in shale gas exploration of underexplored plays， sequences and new types in China [J]. Oil & Gas Geology, 2024, 45(2): 309-326.
[7]	Zhe ZHAO, Bin BAI, Chang LIU, Lan WANG, Haiyan ZHOU, Yuxi LIU. Current status， advances， and prospects of CNPC’s exploration of onshore moderately to highly mature shale oil reservoirs [J]. Oil & Gas Geology, 2024, 45(2): 327-340.
[8]	Bo LIU, Qi’an MENG, Xiaofei FU, Tiefeng LIN, Yunfeng BAI, Shansi TIAN, Jinyou ZHANG, Yao YAO, Xinyang CHENG, Zhao LIU. Composition of generated and expelled hydrocarbons and phase evolution of shale oil in the 1^st member of Qingshankou Formation， Songliao Basin [J]. Oil & Gas Geology, 2024, 45(2): 406-419.
[9]	Xiao HE, Maja ZHENG, Yong LIU, Qun ZHAO, Xuewen Shi, Zhenxue Jiang, Wei WU, Ya WU, Shitan NING, Xianglu TANG, Dadong LIU. Characteristics and differential origin of Qiongzhusi Formation shale reservoirs under the “aulacogen-uplift” tectonic setting， Sichuan Basin [J]. Oil & Gas Geology, 2024, 45(2): 420-439.
[10]	Changbo ZHAI, Liangbiao LIN, Donghua YOU, Fengbin LIU, Siyu LIU. Sedimentary microfacies characteristics and organic matter enrichment pattern of the 1^st member of the Middle Permian Maokou Formation， southwestern Sichuan Basin [J]. Oil & Gas Geology, 2024, 45(2): 440-456.
[11]	Hequn GAO, Yuqiao GAO, Xipeng HE, Jun NIE. Rock mechanical properties and controlling factors for shale oil reservoirs in the second member of the Paleogene Funing Formation， Subei Basin [J]. Oil & Gas Geology, 2024, 45(2): 502-515.
[12]	Liang SHI, Bojiang FAN, Zhonghou LI, Ziwei YU, Zijin LIN, Xinyang DAI. Migration differentiation of hydrocarbon components in the 7^th member of the Triassic Yanchang Formation， central Ordos Basin [J]. Oil & Gas Geology, 2024, 45(1): 157-168.
[13]	Yi ZHANG, Bin ZHANG, Banghua LIU, Jie LIU, Qiansheng WEI, Qi ZHANG, Hongjun LU, Pengyu ZHU, Rui WANG. Status quo and development trends of research on shale gas adsorption and seepage in shale gas reservoirs [J]. Oil & Gas Geology, 2024, 45(1): 256-280.
[14]	Dujie HOU, Keqiang WU, Li YOU, Ziming ZHANG, Yajun LI, Xiaofeng XIONG, Min XU, Xiazhe YAN, Weihe CHEN, Xiong CHENG. Organic matter enrichment mechanisms of terrigenous marine source rocks in the Qiongdongnan Basin [J]. Oil & Gas Geology, 2024, 45(1): 31-43.
[15]	Xusheng GUO, Xiaoxiao MA, Maowen LI, Menhui QIAN, Zongquan HU. Mechanisms for lacustrine shale oil enrichment in Chinese sedimentary basins [J]. Oil & Gas Geology, 2023, 44(6): 1333-1349.